WO2003001266A1

WO2003001266A1 - Optical transmission element

Info

Publication number: WO2003001266A1
Application number: PCT/DE2002/002216
Authority: WO
Inventors: Reiner Schneider; Edgar Heinz; Frank Koschwitz
Original assignee: Ccs Technology, Inc.
Priority date: 2001-06-20
Filing date: 2002-06-18
Publication date: 2003-01-03
Also published as: JP2004530936A; US20040156603A1; US7349607B2; DE10129772A1; DE10129772B4; JP4237612B2

Abstract

At least one dry and compressible fixing element (FE11 to FE13) is situated between an optical waveguide (LF11, LFB12, LFB13) and a surrounding chamber element (AH11, AH12, SB13) of an optical transmission element (OE11 to OE13). Said fixing element completely or partially surrounds the optical waveguide and exerts a defined application pressure onto the chamber element and onto the optical waveguide in order to fix the optical waveguide in the longitudinal direction of the transmission element. In addition, the fixing element is designed and placed in a manner that permits changes in position of the optical waveguide caused by bending and stretching. This enables the prevention of impermissible increases in attenuation inside the optical waveguide that result from bending or from changes in the length.

Description

description

Optical transmission element

The present invention relates to an optical

Transmission element with at least one optical waveguide and with a chamber surrounding the optical waveguide.

Optical transmission elements such as optical cables or optical wires are often laid during installation in such a way that the cable or wire ends hang vertically at the connection points. This can lead to the fact that the optical fibers contained in the cable or in the wire, which are usually in the cable or in the wire with a defined excess length, partially migrate out, for example as a result of gravity. Migration of the optical fibers is a problem, particularly in the area of connection sleeves, since the fibers that slide into the connection sleeve as a result of migration outward can bend and break in the process.

A common method of fixing the optical fibers in an optical transmission element is to fill the chamber with a highly viscous, thixotropic or crosslinking filler. Such a filling compound has the disadvantage that it can run out or drip out in the case of vertically hanging ends of the transmission element. In addition, in the event of the transmission element being separated during installation, the filling compound escaping during installation can lead to contamination and handling problems on the part of the assembly personnel.

In the case of dry, unfilled optical cables, swelling fleeces are often used to seal the cable when water enters. These are designed such that they

Swell water ingress and thereby seal the cable. However, such a swelling fleece generally fills the There is no space between the optical fibers and the surrounding chamber element, so that the fibers cannot be fixed by the swelling fleece.

The object of the present invention is to provide an optical transmission element with at least one optical waveguide and with a chamber element surrounding the optical waveguide, in which the optical waveguide is fixed in a defined manner in the longitudinal direction of the transmission element and yet inadmissible attenuation increases in the optical waveguide due to bending or changes in length of the transmission element are avoided ,

The object is achieved by an optical transmission element according to patent claim 1.

The optical waveguide is fixed in the chamber element by a dry and compressible fixing element which is arranged between the optical waveguide and the chamber element. It completely or partially surrounds the optical waveguide and exerts a defined contact force against the chamber element and against the optical waveguide, so that a certain fixation of the optical waveguide in the longitudinal direction of the transmission element is thereby achieved. By further designing and arranging the fixing element in such a way that changes in position of the optical waveguide caused by bending or stretching are permitted, inadmissible increases in attenuation in the optical waveguide due to bending or changes in length can be avoided. Because of the compressible structure of the fixing element

Changes in position to a certain extent are possible, the optical waveguide, for example in the form of one or more optical fibers, has a certain amount of freedom and mobility, so that, for example when bending the optical transmission element, there are no unacceptable increases in attenuation. In an advantageous embodiment of the invention, the fixing element contains an elastic foam sheet or is designed as an elastic foam sheet. The foam sheet advantageously contains an elastomer foam, in particular polyurethane foam, polyether foam or polyester foam. With the help of the foam sheet, a defined setting of the contact pressure and the correct friction with respect to the optical waveguide is made possible, but due to the flexible design of the foam sheet certain position changes of the optical waveguide are made possible.

In a further embodiment of the invention, the fixing element contains a fibrous, fluffy material. Such a material has essentially similar properties to the foam film described above. For example, cotton, fiber fill or velvet-like pads with low density and high flexibility or good deformability can be used. Like the foam film described above, such a fixing element also advantageously serves as a crush protection for the optical waveguide.

In a further embodiment of the invention, the fixing element is designed in the form of a compressible round cord which is wound around the optical waveguide. The fixing element can also be designed as a profile adapted to the cross-sectional shape of the comb element and the optical waveguide. Profiles in the form of a U-profile or slotted round profile are particularly suitable for this.

In a particularly advantageous embodiment of the

According to the invention, a plurality of separate fixing elements are arranged in the longitudinal direction of the transmission element with intermediate spaces lying between them, which are not occupied by fixing elements. In the gaps, optical fibers can move comparatively well when the transmission element is bent, so that increases in attenuation are prevented. For this purpose, the respective intermediate spaces advantageously have one greater longitudinal extension than the respective fixation elements. This also enables several optical fibers, which are stranded together, to form an almost undisturbed excess length helix in the transmission element. So that the fibers can move well when bending the transmission element at least within half a lay length, the longitudinal extent of the respective intermediate spaces is advantageously at least half a lay length of the respective stranded optical waveguide.

In one embodiment of the invention, the plurality of separate fixing elements are arranged in the longitudinal direction of the transmission element on a carrier film connecting the fixing elements. In order to ensure that the transmission element is watertight, the carrier film is advantageously designed to swell at least on one side, for example by providing it with a swelling fleece. A very good watertightness can be achieved in the transmission element because of the penetration

Water is braked strongly at each fixation element and can therefore only spread very slowly in the longitudinal direction. The swellable side of the carrier film that is exposed between the fixing elements can swell undisturbed in the slowly flowing water and quickly seals the free space between the optical waveguides and the chamber element.

A carrier film with swelling agent detaching from the belt can also be used for this purpose, since the detaching swelling substance cannot be washed away to any appreciable extent due to the greatly slowed down flow rate of penetrating water. In the event that the source substance is detached by water flowing along, it attaches again to the subsequent fixing element. As a result, the transmission element is sealed after only a few centimeters. To further improve the sealing of the transmission element, the fixing element is mixed with a swellable agent or laminated with swelling film. For example, the swelling substance in powder form is stored in spaces between the fixing element, for example in the foam pores of the foam sheet or in spaces between the fibrous, fluffy material.

A further embodiment of the fixing element can be a foam sheet that is laminated on one or both sides with a swelling sheet. For this, swellable nonwovens are preferably used, in which the side containing the swelling agent faces the foam of the foam sheet. Since the foam filling the space between the optical waveguide and the chamber element strongly brakes the incoming water, the water can only spread very slowly along the transfer element. The swellable substance therefore seals the cable after just a few centimeters. It is also advantageous that the swelling agent is held firmly in the foam or in the fibrous, fluffy material and cannot be washed away.

Further advantageous developments and developments of the invention are specified in the claims below.

The invention is explained in more detail below with reference to the figures shown in the drawing, which illustrate exemplary embodiments of the invention. Show it:

Figures 1 to 3 each cross-sectional views of

Embodiments of an optical transmission element according to the invention,

FIG. 4 shows a longitudinal section of an embodiment of an optical wire, FIG. 5 shows a perspective view of a foam sheet with a carrier sheet,

FIG. 6 shows a perspective view of an optical cable,

7 shows a longitudinal section of another

Embodiment of an optical wire,

Figure 8 is a perspective view of several

Foam films on a carrier film,

FIG. 9 shows a perspective view of an optical cable during manufacture,

1.5

FIGS. 10 and 11 each show perspective views of further embodiments of an optical transmission element according to the invention.

20

FIG. 1 shows an optical transmission element OEll in the form of a cable which has a plurality of optical waveguides LFll in the form of individual fibers. The individual fibers LFll are surrounded by a core sheath AHll, with between the fibers

25 LFll and the ferrule AHll a fixing element FEH is arranged in the form of a compressible foam sheet. This foam sheet surrounds the individual fibers almost completely (a slit SL is formed by laying the foam sheet around the fibers) and exerts a defined contact pressure

30 the wire sheath AHll and against the individual fibers LFll and thus fixes the fibers in the longitudinal direction of the cable. The flexible configuration of the foam sheet enables changes in the position of the fibers, for example as a result of bending or stretching of the cable. The core sheath is AHll

35 surrounded by a swelling fleece QV11, which in turn is covered by

Aramid yarn AG11 is enclosed. The cable is terminated by the KM11 cable sheath. FIG. 2 shows a transmission element OE12 which has optical waveguides in the form of fiber ribbons LFB12. A fixing element FE12 in the form of a foam sheet is arranged between the wire sheath AH12 and the fiber tapes LFB12. This fulfills the same function as the foam sheet according to FIG. 1. The wire sheath AH12 is surrounded by aramid yarns AG12, and tensile GFK elements ZE12 are embedded in the cable sheath KM12.

FIG. 3 shows a transmission element OE13 which has an optical waveguide LFB13 in the form of a 3 × 12 fiber bundle. A FE13 fixing element in the form of a foam sheet is arranged between a steel strip SB13 and the fiber bundle LFB13. Tensile steel wires ZE13 are embedded in the KM13 cable sheath.

In all three examples according to FIGS. 1 to 3, the fixation of the fibers in the cable is generated by the respective elastic foam film that surrounds the fibers. The cross section of the film is dimensioned such that the space between the fibers and the chamber surrounding the fibers is completely or largely filled, and a defined contact pressure is generated on the fibers and on the chamber wall. The foam sheet preferably contains an elastomer foam with a high coefficient of friction, such as, for example, polyurethane foam, polyether foam or polyester foam. Foam foils with densities between 10 and 100 kg / m ³ are preferably used. The foam of the foam sheet is preferably open-pore.

FIG. 4 shows a longitudinal section of an embodiment of an optical wire OE1, in which the optical fibers LF are stranded together and are introduced in an excess length into the chamber formed by the wire sheath AH. There is one between the optical fibers LF and the wire sheath AH continuously arranged compressible foam film SF, which is attached to a carrier film TF, arranged.

FIG. 5 shows a perspective view of a foam sheet SF which is arranged on a carrier sheet TF. The carrier film TF is preferably designed as a swelling film. Good watertightness of the optical transmission element can thereby be achieved, since penetrating water is braked at the boundary of the foam sheet by its swelling.

FIG. 6 shows a perspective view of an optical cable 0E2, which contains optical fibers LF, surrounded by a foam sheet SF, in a wire sheath AH, which in turn is surrounded by a cable sheath KM. The foam sheet SF is formed into a tube around the fibers LF and is encased by the wire sheath AH or by the cable sheath KM.

FIG. 7 shows a longitudinal section of a further embodiment of an optical wire 0E3. There are several separate compressible foam foils SF1 to SF3 arranged in the longitudinal direction of the transmission element OE3 with intermediate spaces ZR1 and ZR2 which are not occupied by foam. The foam films SF1 to SF3 are arranged in the longitudinal direction of the transmission element OE3 on a carrier film TF. The optical fibers LF are stranded lengthways and can form an almost undisturbed excess length helix in the transmission element due to the spaces ZR1 and ZR2. The spaces ZR1 and ZR2 have a greater longitudinal extension than the respective ones

Foam foils SF1 to SF3. This is preferably more than half the lay length of the optical fibers. The optical fibers LF can thus be displaced well when the transmission element OE3 is bent, as a result of which attenuation increases, for example as a result of the bending radii of the optical fibers being too small, being prevented. The carrier film TF is designed as a swelling film in order to produce good watertightness. In the example, it is designed to swell on the side facing the foam sections. Penetrating water is braked strongly at each of the foam film sections and can therefore only spread very slowly in the longitudinal direction. The swelling material exposed between the foam film sections can swell undisturbed in the slowly flowing water and quickly seals the free space between the fibers LF and the buffer tube AH. However, swelling tapes with swelling agent detaching from the tape can also be used in this connection, because the detaching swelling substance cannot be washed away to any appreciable extent due to the greatly slowed flow rate of the penetrating water. Source substance that is nevertheless washed away can accumulate on each of the foam film sections.

FIG. 8 shows a perspective view of a plurality of foam film sections SF1, SF2 on a carrier film TF. The carrier film TF is swellable at least on the side QS, preferably provided with a swelling fleece. The swellable side QS of the carrier film TF faces the foam film sections SF1, SF2 arranged thereon. The foam film sections are attached to the carrier film TF at appropriate intervals, for example glued.

For a particularly good seal, the foam foils, which fill the entire space between the fibers and their protective cover in the uncompressed state, are mixed with a substance that swells when water enters. This swelling substance can be stored in powder form in the foam pores. In a further embodiment, the respective foam film can be laminated on one or both sides with a swelling film. Swellable nonwovens are preferably used for this, the swelling agent-containing side facing the foam of the foam sheet. The swelling agent is advantageously held in the foam and cannot be washed away become. The foam filling the intermediate space brakes incoming water strongly, so that it can only spread very slowly along the transmission element. The swellable substance seals the transmission element after just a few centimeters.

FIG. 9 shows a perspective view of an optical cable OE4 during manufacture. The foam film sections SF1 to SF3 arranged on the carrier film TF are formed into a tube around the fibers LF and are encased in a wire sheath AH and a cable sheath KM. The foam sheets SF1 to SF3 as well as the foam sheet SF. According to FIG. 6 are a prefabricated product and are comparatively inexpensive to manufacture. The outlay on equipment for producing the cable can thus be kept comparatively low.

FIG. 10 shows a perspective view of an embodiment of an optical transmission element, in which the optical fibers LF are wrapped by a fixing element in the form of a compressible round cord RS. The round cord RS is supported on the outside against a chamber wall, not shown.

FIG. 11 shows a further embodiment of a transmission element, in which the fixing element is designed as a profile PF, which is adapted to the respective cross-sectional shape of a chamber element (not shown) and the optical waveguide LFB. The profile PF here has the shape of a U-profile.

Claims

claims

1.Optical transmission element (OEll to OE13) with at least one optical waveguide (LFll, LFB12, LFB13) and with a chamber element (AHll, AH12, SB13) surrounding the optical waveguide, in which at least one dry and compressible fixing element (between the optical waveguide and the chamber element FEH to FE13) is arranged, which completely or partially surrounds the optical waveguide and exerts a defined contact force against the chamber element and against the optical waveguide for fixing the optical waveguide in the longitudinal direction of the transmission element and which is further designed and arranged in such a way that changes in position caused by bending or stretching of the optical fiber are enabled.

2. Optical transmission element according to claim 1, that the fixing element contains an elastic foam film (SF, SF1 to SF3).

3. Optical transmission element according to claim 2, that the foam film contains an elastomer foam, in particular polyurethane foam, polyether foam or polyester foam.

4. Optical transmission element according to claim 2 or 3, characterized in that the foam sheet has a density between 10 and 100 kg / m ³ .

5. Optical transmission element according to one of claims 2 to 4, characterized in that the foam sheet is laminated with a swelling sheet (TF), a swellable side of the swelling sheet facing the foam sheet.

5 6. Optical transmission element according to one of claims 2 to 5, d a d u r c h g e k e n n z e i c h n e t that the foam of the foam sheet is open-pore.

0 7. Optical transmission element according to one of claims 1 to 6, d a d u r c h g e k e n n z e i c h n e t that the fixing element (FEH to FE13) contains a fibrous, fluffy material. -5

8. Optical transmission element according to claim 7, d a d u r c h g e k e n n z e i c h n e t that the fixing element contains cotton, fiber-fill or a velvet-like cushion. 0

9. Optical transmission element according to one of claims 1 to 8, d a d u r c h g e k e n n z e i c h n e t that the fixing element is in the form of a compressible round cord 5 (RS) which is wound around the optical fiber (LF).

10. Optical transmission element according to one of claims 1 to 8, 0 characterized in that the fixing element as a to the cross-sectional shape of the chamber belt s and the optical waveguide profile (PF), in particular in the form of a U-profile (PF) or slotted round profile (FE12 ) is trained. 5

11. Optical transmission element according to one of claims 1 to 10, characterized in that the fixing element (SF, SF1 to SF3) essentially fills a space between the optical waveguide and the chamber element at least along a partial length of the transmission element.

12. Optical transmission element according to one of claims 1 to 11, d a d u r c h g e k e n n z e i c h n e t that several separate fixing elements (SFl to SF3) in

The longitudinal direction of the transmission element (OE3) are arranged with intermediate spaces (ZR1, ZR2) which are located between them and are not occupied by fixing elements.

13. Optical transmission element according to claim 12, so that the respective gaps (ZR1, ZR2) have a greater longitudinal extent than the respective fixing elements (SF1 to SF3).

14. Optical transmission element according to claim 12 or 13, so that the optical waveguide (LF) is longitudinally stranded and a longitudinal extent of the respective intermediate spaces (ZR1, ZR2) is at least half the lay length of the stranded optical waveguide.

15. Optical transmission element according to one of claims 1 to 14, so that several separate fixing elements (SF1, SF2) are arranged in the longitudinal direction of the transmission element on a carrier film (TF) connecting the fixing elements.

16. Optical transmission element according to claim 15, characterized in that the carrier film is designed to be swellable on at least one side (QS) for sealing when water enters.

17. Optical transmission element according to claim 16, so that the carrier film is provided with a swelling fleece (QS) or with detachable swelling agent.

18. Optical transmission element according to claim 16 or 17, so that the swellable side (QS) of the carrier film faces the fixing elements (SF1, SF2) arranged thereon.

19. Optical transmission element according to one of claims 1 to 18, so that the fixing element is sealed with a swellable agent or is covered with a swelling film for sealing when water enters.

20. Optical transmission element according to claim 19, so that the swellable agent is stored in powder form in the interstices of the fixing element.